Output production

ABSTRACT

Systems, methods, and other embodiments associated with output production are described. One example system comprises an analysis component configured to analyze a data set to produce an evaluation result. The system also comprises a production component configured to produce a rendered output based, at least in part, on the evaluation result, where the rendered output is stored in a computer-readable medium.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. provisional application Ser.No. 61/409,027 filed on Nov. 1, 2010, which is hereby whollyincorporated by reference.

This application claims the benefit of, and is a continuationapplication of, U.S. application Ser. No. 13/194,946 filed on Jul. 30,2011, which is hereby wholly incorporated by reference.

BACKGROUND

A user can play a video game on the video game console, where theconsole outputs content onto a display. For example, the video game canbe a management game played on a personal computer. The management gamecan enable a player to take control of an entity, such as a railroadcompany. The player can lead the company through different scenarios,manage the company in an open world, compete against other players, etc.

BRIEF DESCRIPTION OF THE FIGURES

The accompanying drawings, which are incorporated in and constitute apart of the detailed description, illustrate various example systems,methods, and other example embodiments of various innovative aspects.These drawings include:

FIG. 1 illustrates one embodiment of a system that includes an analysiscomponent and a production component;

FIG. 2 illustrates one embodiment of a system that includes a searchcomponent along with the analysis component and the productioncomponent;

FIG. 3 illustrates one embodiment of a system that includes aninteraction component, evaluation component, and gather component, alongwith the analysis component and production component;

FIG. 4 illustrates one embodiment of a map area;

FIG. 5 illustrates one embodiment of a system that includes analteration component along with the analysis component and theproduction component;

FIG. 6 illustrates one embodiment of a system that includes a collectioncomponent and a render component;

FIG. 7 illustrates one embodiment of a system that includes anidentification component and an approximation component along with thecollection component and the render component;

FIG. 8 illustrates one embodiment of a system that includes a monitorcomponent, an appraisal component, and a decision component in additionto the collection component and the render component;

FIG. 9 illustrates one embodiment of a system that includes anassessment component, determination component, filter component, andoutput component;

FIG. 10 illustrates one embodiment of a system that includes anobtainment component, a gather component, a generation component, and atransfer component;

FIG. 11 illustrates one embodiment of a system that includes anexamination component, an identification component, a separationcomponent, and a generation component;

FIG. 12 illustrates one embodiment of a system that includes theexamination component, the identification component, an approximationcomponent, and a composition component;

FIG. 13 illustrates one embodiment of a system that includes theexamination component, the identification component, the compositioncomponent, and a database component;

FIG. 14 illustrates one embodiment of a network;

FIG. 15 illustrates one embodiment of a method that includes retaining avideo game content at a first location and causing the video gamecontent to be available to a second location;

FIG. 16 illustrates one embodiment of a method that includes retaining avideo game content at a first location and causing the video gamecontent to be available to a second location;

FIG. 17 illustrates one embodiment of a method that resolves adifference between maps;

FIG. 18 illustrates one embodiment of a method that causes a map to bemade;

FIG. 19 illustrates one embodiment of a town grouping;

FIG. 20 illustrates one embodiment of an interface;

FIG. 21 illustrates one embodiment of a system that may be used inpracticing at least one aspect disclosed herein; and

FIG. 22 illustrates one embodiment of a system, upon which at least oneaspect disclosed herein can be practiced.

It will be appreciated that illustrated element boundaries (e.g., boxes,groups of boxes, or other shapes) in the figures represent one exampleof the boundaries. One of ordinary skill in the art will appreciate thatin some examples one element may be designed as multiple elements orthat multiple elements may be designed as one element. In some examples,an element shown as an internal component of another element may beimplemented as an external component and vice versa. Furthermore,elements may not be drawn to scale. These elements and other variationsare considered to be embraced by the general theme of the figures, andit is understood that the drawings are intended to convey the spirit ofcertain features related to this application, and are by no meansregarded as exhaustive or fully inclusive in their representations.Additionally, it is to be appreciated that the designation ‘FIG.’represents ‘Figure’. In one example, ‘FIG. 1’ and ‘FIG. 1’ are referringto the same drawing.

The terms ‘may’ and ‘can’ are used to indicate a permitted feature, oralternative embodiments, depending on the context of the description ofthe feature or embodiments. In one example, a sentence states ‘A can beAA’ or ‘A may be AA’. Thus, in the former case, in one embodiment A isAA, and in another embodiment A is not AA. In the latter case, A may beselected to be AA, or A may be selected not to be AA. However, this isan example of A, and A should not be construed as only being AA. Ineither case, however, the alternative or permitted embodiments in thewritten description are not to be construed as injecting ambiguity intothe appended claims. Where claim ‘x’ recites A is AA, for instance, thenA is not to be construed as being other than AA for purposes of claim x.This is construction is so despite any permitted or alternative featuresand embodiments described in the written description.

DETAILED DESCRIPTION

Described herein are example systems, methods, and other embodimentsassociated with output production, such as producing a map for a videogame. One example type of video game is a racing video game. Whileexamples to the racing video game are described herein to describeaspects, it is to be appreciated other type of video games can beemployed according to those aspects, as well as other types of non-videogame applications.

With this racing video game, a disk can be sold in a store that includesnot only the application of the game (e.g., code used by a console toenable a user to play the game), but also game content. Example gamecontent can include different cars and different tracks that the playercan race the cars upon. Due to limited disk space, a limited number oftracks can be available on the disk. To obtain more tracks, players canspend additional funds for additional downloadable content that includesother tracks. However, even with available downloadable tracks andtracks sold with the disk, a relatively limited number of tracks can bemade available to the user.

To alleviate this problem, a system can be used to create tracks for theuser. These tracks can be created based upon a user request (e.g.,automatically created). For example, a user can desire to race at atrack not included in the game. The user can submit a request to his orher game console and in response to the request, information pertainingto the request can be gathered and a track can be generated (e.g., atthe console, at a remote location, etc.). The user can use the track andthe track can be made available to other players. As used herein, aremote location can refer to, but is not limited to, a first system. Thefirst system and a second system can be two distinct systems that arenot directly connected to one another and separated by physical distancethat interact via at network or data link such as, for example, theInternet, a local area network, infrared ports, and soforth, in a wiredor wireless fashion.

The following paragraphs include definitions of selected terms discussedat least in the detailed description. The definitions may includeexamples used to explain features of terms and are not intended to belimiting. In addition, where a singular term is disclosed, it is to beappreciated that plural terms are also covered by the definitions.Conversely, where a plural term is disclosed, it is to be appreciatedthat a singular term is also covered by the definition. In addition, aset can include one or more member(s).

References to “one embodiment”, “an embodiment”, “one example”, “anexample”, and so on, indicate that the embodiment(s) or example(s) sodescribed may include a particular feature. The embodiment(s) orexample(s) are shown to highlight one feature and no inference should bedrawn that every embodiment necessarily includes that feature. Multipleusages of the phrase “in one embodiment” and others do not necessarilyrefer to the same embodiment; however this term may refer to the sameembodiment. It is to be appreciated that multiple examples and/orembodiments may be combined together to form another embodiment.

“Computer-readable medium”, as used herein, refers to a medium thatstores signals, instructions, and/or data. A computer may access acomputer-readable medium and read information stored on thecomputer-readable medium. In one embodiment, the computer-readablemedium stores instruction and the computer can perform thoseinstructions as a method. The computer-readable medium may take forms,including, but not limited to, non-volatile media (e.g., optical disks,magnetic disks, and so on), and volatile media (e.g., semiconductormemories, dynamic memory, and so on). Example forms of acomputer-readable medium may include, but are not limited to, a floppydisk, a flexible disk, a hard disk, a magnetic tape, other magneticmedium, an application specific integrated circuit (ASIC), aprogrammable logic device, a compact disk (CD), other optical medium, arandom access memory (RAM), a read only memory (ROM), a memory chip orcard, a memory stick, and other media from which a computer, a processoror other electronic device can read.

“Component”, “logic”, “module”, “interface” and the like as used herein,includes but is not limited to hardware, firmware, software stored or inexecution on a machine, a routine, a data structure, and/or at least onecombination of these (e.g., hardware and software stored). Component,logic, module, and interface may be used interchangeably. A componentmay be used to perform a function(s) or an action(s), and/or to cause afunction or action from another component, method, and/or system. Acomponent may include a software controlled microprocessor, a discretelogic (e.g., ASIC), an analog circuit, a digital circuit, a programmedlogic device, a memory device containing instructions, a process runningon a processor, a processor, an object, an executable, a thread ofexecution, a program, a computer and so on. A component may include oneor more gates, combinations of gates, or other circuit components. Wheremultiple components are described, it may be possible to incorporate themultiple components into one physical component. Similarly, where asingle component is described, it may be possible to distribute thatsingle component between multiple physical components. In oneembodiment, the multiple physical components are distributed among anetwork. By way of illustration, both/either a controller and/or anapplication running on a controller can be one or more components.

FIG. 1 illustrates one embodiment of a system 100 that includes ananalysis component 105 and a production component 110. The analysiscomponent 105 can be configured to analyze a map data set 115 to producean evaluation result. The production component 110 can be configured toproduce a rendered map 120 based, at least in part, on the evaluationresult, where the rendered map is stored in a computer-readable medium(e.g., made available for use from the computer readable medium).

In one embodiment, the production component 110 can produce the renderedmap 120 configured for use in a video game. In one embodiment, therendered map 120 is a file that can be used by a video game console orother electronic device to produce a playable map in a video game. In anembodiment, the playable map was not included in the game's originalcontent or developed for mass-use by a particular entity, but generatedon-demand based on an individual end user's desire to participate in apreviously un-modeled environment in the game setting. In oneembodiment, the rendered map 120 is content produced on a displayscreen.

In one embodiment, a player can play a racing video game that enablesthe player to drive a video game race car (e.g., 2008 Ford Mustang GT)upon a video game race track (e.g., Indianapolis Motor Speedway). Thisvideo game race track may be based off a real race track and included ona disk of the video game. Tracks included on the disk can be considereda video game track set. The player may want to race in the video game ona specific track not included in the video game track set. Therefore,the system 100 may operate to create the specific track, or a pluralityof tracks that are not pre-established within the shipped package.

Under the disclosures set forth herein, one or more systems or processescan have instances where workers (e.g., truck drivers, law enforcement,military personnel) can train on an area they are going into. In oneexample, the President of the United States can visit Elkhart, Ind. Aspart of Secret Service training, the rendered map 120 can be createdproactively of a current state of Elkhart roads and agents can train onthe map. This can allow realistic training that can be enabled atminimal expense and in an ongoing, timely fashion. Being able to rendernavigable or interactive maps using available data can have multipleapplications.

Aspects disclosed herein can apply to various applications, subjectmatters, etc. Example areas where aspects disclosed herein can bepracticed include video games (e.g., first person, third person, userinterfaces or controls as replicated in games, etc.), simulators (e.g.,ground vehicle, flight, ship, etc.), training systems, operationrehearsals (e.g., dismounted military mission, convoy preparation,commercial logistics, etc.), leisure, planning, navigation, virtualsightseeing or visitation, modeling and other predictive, optimizationor analytical utilities dependent upon accurate reflections of space andtime, etc. It is to be appreciated that these example areas are not anexhaustive list.

FIG. 2 illustrates one embodiment of a system 200 that includes a searchcomponent 205 along with the analysis component 105 and the productioncomponent 110. The search component 205 can be configured to determineif a base map 210 for the rendered map 120 is available. The base mapcan be considered is at least part of the map data set (e.g., theanalysis component 105 analyzes the base map to determine if the basemap meets a criteria set (e.g., one or more criterion) and theproduction component 110 designates the base map as the rendered map,with this designation being an output). The search component 205 canoperate at varying granular levels, determining if portions of the basemap 210 are sufficiently current or if one or more possible base mapscan be extracted or combined to provide a more (e.g., the most)desirable search results.

FIG. 3 illustrates one embodiment a system 300 that includes aninteraction component 305, evaluation component 310, and gathercomponent 315, along with the analysis component 105 and productioncomponent 110. The interaction component 305 can be configured toreceive a request 320 for the rendered map 120. The evaluation component310 can be configured to evaluate the request 320 that produces anevaluation result, where the evaluation result indicates information togather to produce the rendered map 120 (e.g., what data should begathered as part of the map data set 115). The gather component 315 canbe configured to gather the map data set 115 according to theinformation the evaluation result indicates to gather, where the mapdata set 115 is gathered prior to analysis by the analysis component105.

In one example, the player can make the request 320 (e.g., through auser interface) to race at Circuit de Monaco, home of the Monaco GrandPrix, in his video game. The interaction component 305 receives therequest 320 and the evaluation component 310 evaluates the request. Aspart of this evaluation, the evaluation component 310 can determine whatinformation should be gathered to meet the user's request. The gathercomponent 315 can 100 to locate information available on the Circuit deMonaco and collect such information. In one example, racing websites, aweb mapping service application, and other locations (e.g., onlinelocations) can be searched to gather information (e.g., map data of themap data set 115) about the Circuit de Monaco. Based on informationgathered, the production component 110 can generate a video game versionof the Circuit de Monaco and output the video game version (e.g., as therendered map 210).

In one example, the player can make a request 320 (e.g., entered with avideo game console controller) and this requested is received by theinteraction component 305. The request can be to race at Burke LakefrontAirport, home of the Cleveland Grand Prix from 1982-2007. The gathercomponent 315 can be employed to locate information available on BurkeLakefront Airport. In one example, racing websites, a web mappingservice application, and other locations (e.g., online locations) can besearched to gather information (e.g., map data of the map data set 115)about the Burke Lakefront Airport. However, since a historical track isrequested, other information may be used to determine how to render avideo game version of Burke Lakefront Airport (e.g., historical weatherinformation, different surface information based on repairs, etc.). Inaddition, different track layouts may be used during different years forthe Cleveland Grand Prix (e.g., 1989 Cleveland Grand Prix had adifferent track layout than 1990 Cleveland Grand Prix). To determinewhich layout to create, the interaction component 305 can ask the playerfor more information (e.g., ask player which track should be rendered)or query one or more sources of information (e.g., compare with previoustelevision watching to see if the player watched a particular race andmaking an inference that the track the player wants is the track hewatched). In one embodiment, the production component 310 producesdifferent layouts (e.g., the 1989 layout and 1990 layout) in response tothe request 320 (e.g., when a specific layout for the request cannot beascertained) and makes these layouts available to the player. Thesources of information that make up the map data set 115 can be publicor private, or a variant in between—for example, specific data orpointers/links to data can be stored in/on the video game, private orproprietary databases can be interrogated, public information can beinvestigated locally (e.g., local hard drive) or via a network (e.g.,Wikipedia), and others. Based on information gathered, the productioncomponent 110 can generate a video game version of the Circuit de Monacoand output the video game version (e.g., as the rendered map 120).

While visual rendering can be performed, other rendering may beperformed. In one example, in auto racing, track temperature can beimportant in determining how a car handles and other factors. A trackcan be rendered with temperature information (e.g., in addition tovisual rendering). With rendering with temperature information, thetrack can represent properties relevant to the temperature (e.g., acolder track can cause a car to respond differently than a warmertrack). In one example, real-time or recently taken temperatureinformation can be used in rendering (e.g., from a taken tracktemperature reading, an inference drawn from air temperature over aperiod (e.g., the air temperature can indicate track temperature basedon track surface type), and others). In one example, average temperaturecan be used to determine track temperature.

In one example, asphalt in Cleveland may behave differently than asphaltin Miami. Rendered asphalt (e.g., in a video game) can be based onasphalt in those locations. In one example, track can be based onreal-time weather information (e.g., rain, temperature, sun exposure,and others). Different characteristics can be given to different partsof one track (e.g., start of course has different track temperature thanend of course).

In an embodiment, a track can provide canned characteristic. In oneexample, a rendered track can show a temperature of ‘x’ degrees. Thisinformation can be given to a game and the game can have a car respondin a certain manner based on the temperature.

In one embodiment, a player can request a rendered map of IndianapolisMotor Speedway. A track at Indianapolis Motor Speedway can be arrangedin different configurations. For example, an Indianapolis 500configuration can configure as a squared oval while an IndianapolisGrand Prix (motorcycle race) configuration can configure as a roadcourse. In one embodiment, the production component 110 can produce arendered map of the Indianapolis Motor Speedway such that a user canselect a configuration, a configuration can be proactively brought outby a video game (e.g., default squared oval, but player can select roadcourse), and others. For example, the rendered map 120 can be producedwhile including track configurations for modern Indianapolis 500, aclassic Indianapolis 500 (e.g., brick-covered track, partiallybrick-covered track, pre-brick crushed stone and tar track, etc.), aFormula One Grand Prix (a defunct race), or the Indianapolis Grand Prixmotorcycle race. In one embodiment, a configuration is selected and highdetail levels are given to track aspects that relate to theconfiguration while low detail levels are given to track aspects that donot relate to the configuration (e.g., if oval is selected, road coursespecific aspects can be given visual distance aspects but not berendered with surface attributes such as track temperature).

In one embodiment, the player can request to play at Indianapolis MotorSpeedway with an Indianapolis 500 configuration. The productioncomponent 110 can render the speedway with Indianapolis 500configuration portions in high detail and other configurations inrelatively low detail. Thus, if the player desires to play anotherconfiguration of the Indianapolis Motor Speedway, the low detailportions can be transformed into high detail.

In one embodiment, as a track is played in a video game, the track canhave characteristics changed that change how the game plays. In oneexample, tracks can experience weeping (e.g., where water was seeping upthrough the asphalt and creating dangerous wet spots), tire marks fromother video game cars breaking heavily on a track, and others. The trackcan reflect these changes to influence how a game plays (e.g., later ina game, more rubber on a track can lead to a different gaming result).

FIG. 4 illustrates one embodiment of a map area 400. The map area 400can be at least a part of the rendered map 120 of FIG. 1. In oneexample, a video game can employ an open world concept. In the openworld concept, a player can have a relatively large area to drive a car.In one example, the player can drive various streets of Cleveland, Ohio(e.g., a limited number of streets, streets with postal addresses,drivable areas (e.g., lawns, city parks, and others), and others). Thisdiffers from a track concept, where a player can be limited to drive ona track (e.g., Daytona International Speedway). The rendered map 120 canrepresent an open world concept map, a track concept, etc.

In the open world concept, a vast amount of information can exist, avast amount of possible roads along with scenery can be available, andothers. This can contrast the track concept where drivable roads arefixed, scenery for those roads is smaller than open world scenery, andothers. In addition to preexisting data, other data can be mined orgenerated to expand the boundaries of the world to permit a user totravel such that there are no limitations or boundaries are apparent orencountered (e.g., in a sailing game, an ocean map can be generatedallowing a player to circumnavigate the earth).

Due to the vast amount of information available in the open worldconcept, it may be undesirable to continuously use resources (e.g.,processor, memory, and others) to render an entire, or particularthresholds of, an available open world at one time. In one example, agame can be configured to have a person drive on roads available in theUnited States and Canada. A vast amount of resources could be consumedto render possible road combinations available for possible routes inthe United States and Canada. Therefore, selective rendering can occur(e.g., a selection component that can be part of the system 100 ofFIG. 1) can select what to render.

In one example, a rendered area around a vehicle 405 of a video game isselected (e.g., a distance of ‘X’ around the vehicle 405 on thevehicle's sides). The system 100 of FIG. 1 can render a rendered area410 around the vehicle 405 (e.g., the rendered area is at least part ofthe rendered map 120 of FIG. 1). As the vehicle moves in the map area400, the rendered area 410 can change. In one example, an area withinwhich the world is actively rendered by or in system resources isdistance ‘X’. If the vehicle moves in ‘Y’ direction, then a new renderedarea 410′ can be made around a newly positioned vehicle 405′. Newrendered area 410′ can be rendered entirely, or can merely clear aportion of resources representing the eliminated difference of renderedarea 410 and recycle or use new resources to render the added differenceas a portion of new rendered area 410′. The map area 400 can beconsidered the rendered map 120, a rendered area 410 and/or 410′ can beconsidered the rendered map 120, etc.

In one embodiment, the system 100 of FIG. 1 causes a part of renderedarea 410 that is not part of rendered area 410′ to be deleted whilerendering a part of rendered area 410′ that is not part of rendered area410. In one embodiment, the system 100 of FIG. 1 causes a part ofrendered area 410 that is not part of rendered area 410′ to be retainedin a database while rendering a part of rendered area 410′ that is notpart of rendered area 410 (e.g., thus saving areas once they have beendriven in the game).

The size of the distance ‘X’ can be determined based, at least in part,on one or more factors. In one example, the distance ‘X’ is fixed (e.g.,set by a game programmer). In one example, ‘X’ is based, at least inpart, on how much detail exists in the map area 400 (e.g., more detailmeans a smaller rendered area 410). In one example, ‘X’ is based, atleast in part, on how fast the vehicle 405 is travelling in the game(e.g., faster vehicles have a larger radius since faster vehiclestravels more distance is less time). In one example, ‘X’ is based, atleast in part, on intelligent analysis of player driving style, vehiclespeed, information ascertained for other players of the game, otherfactors, or a combination thereof. In one example, ‘X’ is based, atleast in part, on available system resources. System resources can beanalyzed (e.g., by the analysis component 105 of FIG. 1 or othercomponent) in terms of an absolute metric (e.g., total memory), arelative metric (e.g., percentage-wise commit charge), contextualfactors (e.g., other programs using memory, priority level of otherprograms using memory, etc.), and others.

FIG. 5 illustrates one embodiment of a system 500 that includes analteration component 505 along with the analysis component 105 and theproduction component 110. A video game player can be playing afirst-person shooter video game and desire to have a multi-playersession on a small, uninhabited Pacific island. The search component 205of FIG. 2 can perform a search for a map of the island and determinethat a base map 210 for the island is available. The base map 210 can bea full rendering of the same island that was created for another game, arendering of a part of the island, etc. The base map 210 can beconsidered the map data set 115 of FIG. 1.

The analysis component 105 (or other component) can evaluate the basemap 210 to determine if the base map 210 should be altered (e.g., isalteration necessary for usage, balance accuracy against resource usage,etc.), how the base map 210 should be altered (e.g., how the map shouldbe altered can be information of the map data set 115 of FIG. 1), etc.Based on a result of this evaluation, the alteration component 505 canalter the base map 210. In one embodiment, the alteration component 505is part of the production component 110 such that alteration of the basemap is production of the rendered map 120. Thus, in one embodiment, thebase map is modified to become the rendered map (e.g., by the productioncomponent 110).

In one embodiment, a player can play a video game with the base map 210.New information can be discovered that pertains to the base map. Forexample, a golfing video game can include a specific golf course. Whenthe base map 210 is created, an information source may state that thegrass of greens on the course is Bent Grass. Thus, in the base map 210has the player play on Bent Grass greens. However, a new informationsource can be discovered (e.g., newly available, newly found, acorrection to the information source) that indicates the grass of greensis actually Bermuda Grass. The alteration component 505 can modify thebase map 210 such that the golf course instead has Bermuda Grass greens.This alteration can change how the greens look, how the greens respond(e.g., how the greens play), etc. This alteration can occur while thebase map 210 is being used, not being used, etc. Thus, the rendered map120 can be produced (e.g., by the production component 110) such that apre-rendered map (e.g., base map 210) is altered in accordance with themap data set 115 of FIG. 1 (e.g., information that the greens areBermuda Grass) to become the rendered map 120.

A map can be rendered. After the map is rendered, new information canbecome available (e.g., be made known, be discovered by the system 600,be read, information to make a second data portion more reliable than afirst data portion used to create the map, and others). In one example,the new information can be correction information 605 that corrects anerror of the map.

In one embodiment, the system 500 is remote from the video game console,be located upon the video game console, operate in a non-video gameenvironment, etc. Correction information (e.g., such as the change inthe golfing grass) can be identified (e.g., by the search component 205of FIG. 2). The analysis component 105 can evaluate the correctioninformation and the base map 210 to produce an evaluation result. Thealteration component 505 can determine how to modify the base map 210based on the evaluation result, modify the map, transfer an instructionon how to modify the map, and others. The system 500 (e.g., by way ofthe alteration component 505) can emit a modification output. Themodification output can be an instruction set on how to modify a map, asoftware kernel that proactively modifies a map, and others.

Additionally, the modification output can be transferred to multiplemaps. In one embodiment, multiple iterations of the map can exist ongame consoles. In one example, different consoles can have a renderedmap of a particular city. A determination can be made (e.g., by thesystem 500) that a street becomes one-way during rush hour. Renderedmaps of the particular city can be updated based on the determination.The modification output can be transferred to game consoles and theiterations of the map can exist. In this and other ways, maps can bedynamic based on context and update depending on real or imaginedsituations, or based on user or other preference (e.g., time of day, mapsettings, and others).

In one example, one correction can apply to different specific maps. Inone example, a first map is of a city and a second map is of a countythat includes the city. Both the city map and the county map can includea street with an error (e.g., a light post is in the rendered map thatis not existent in real-life). The modification output can be applied tothe city map and the county map such that the error is corrected. In oneembodiment, different modification outputs can be made (e.g., one forthe county map and one for the city map) and/or after the modificationoutput is produced by the system 500 (e.g., by the alteration component505), it can be copied and/or modified for different maps. In oneembodiment, the system 500 makes different modification outputs fordifferent maps.

In one embodiment, a map can be made up of and/or dependent upon anothermap. In one example, a county can be made up of a group of cities.Therefore, a county map can comprise city maps (e.g., maps of cities inthe county). Thus, there may not actually be a county map in of itself,just a group of city maps that form a county. In one example, themodification output can be used to correct a city map that in turncorrects a county map.

The correction information can be different types of information. In oneexample, an error can be identified in base map 210 and the correctioninformation can be information on how to correct the base map 210 (e.g.,where correcting the base map 210 converts the base map 210 into therendered map 120). In one example, a real-world area can be updated. Inone example, a stop sign can be replaced with another traffic managementnotification device (e.g., yield sign, traffic light, and others). Thecorrection information can be information to update base map 210 (e.g.,a previously rendered map) to reflect the real-world area.

In one embodiment, a user can make modification to a track. In oneexample, the Indianapolis Motor Speedway can configure with a first anda second straightaway that are about fifty feet wide. A player candesire that the width be shortened and the alteration component 505 canmodify the rendered track and/or the track can be rendered with thefirst and the second straightaway being narrowed. In one example, if aplayer desires to widen the track, the rendered map can be modified tonot only widen the track, but modify other aspects (e.g., moving agrandstand, move a barrier wall, eliminate a grandstand, and others) toaccommodate the widening.

In one embodiment, a multiplayer game or application map can be createdand this creation can be based, at least in part, on map information.The multiplayer game or application can be local or over a connection. Agroup of people can play an online fantasy game (e.g., World ofWarcraft) or similar virtual-world application (e.g., Second Life) aswell as other games. A new area of the game can be based off a realarea. In one example, Central Park in New York City or NottinghamForrest in England can be analyzed (e.g., by the analysis component 105)and a map can be rendered with features of these areas playable in theonline fantasy game. In another example, real-life places can beimported (e.g., function as the base map 210) and modified (e.g., by thealteration component 505) to serve as a basis or inspiration for arepresentation of an alternate reality (e.g., the rendered map 120).Components can be employed to analyze and render various aspects of areal-life map or environment according to a scheme set forth in the gameor application.

FIG. 6 illustrates one embodiment of a system 600 that includes acollection component 605 and a render component 610. The collectioncomponent 610 is configured to collect a physical information set. Thephysical information set can be collected from one or more physicalinformation sources (e.g., physical information sources 615, 620, and625) and/or from a remote location (e.g., a remote or local collectiondevice that sends a packaged physical information set to the collectioncomponent 605 that the collection component 605 receives). Thecollection component 610 can also collect information that is not partof the physical information set (e.g., game console requirements). Therender component 610 can be configured to produce a video game output630 based, at least in part, on the physical information set, where thevideo game output 630 is stored on a computer-readable medium. In oneembodiment, the collection component 605 and render component 610 resideupon a video game console (e.g., at least part of the collectioncomponent 605 and at least part of the render component 610).

Example physical information sources include Internet websites,databases, etc. Example physical information that can be part of thephysical information set can include weather information, routeinformation, opinion information (e.g., a group of users say a road isdifficult to drive), visual information, audio information, depthinformation, etc. Physical information can be gleaned from a variety ofsources, including a network or data link to the Internet, localnetworks, direct-connected systems, and communication devices capable ofproviding physical information from sources such as satellites, weathersystems and stations, radio or telephonic communication, proprietarydatabases, geological or other surveys, map datum or data, and others. Abaseline for such data can be ascertained in order to produce an averageresult where differing or conflicting physical information exists, andto fill gaps where physical information is incomplete or imperfect. Itis to be appreciated that this is by no means a limiting list ofphysical information and one of ordinary skill in the art can appreciatethat other information is to be included.

In one embodiment, the physical information set is a physical mapinformation set and where the video game output 630 is a video game map.In one embodiment, the video game map comprises a race course and wherethe video game enables use of the race course in a racing video gameapplication. In one embodiment, the video game map comprises anenvironment upon which an avatar (e.g., human-type character) cannavigate

In one embodiment, the physical information set is voice information andwhere the video game output is video game audio commentary. For example,a college football broadcasting team (e.g., a play-by-play broadcasterand color commentator) can provide audio support for the broadcast of acollege football game. The collection component 605 can obtain a copy ofthe audio support. The render component 610 can break down the audiosupport and extract singular lines (e.g., individual lines for theplay-by-play broadcaster and color commentator related to play on thefield). During game play of a college football video game on a videogame console, the render component 610 can output (e.g., cause a videogame console) of a singular line or multiple lines in response to anoccurrence in gameplay, to set tone of gameplay, etc. For example, if aplayer in the game makes a hard hit, then a common term used by thecolor commentator can be played. As opposed to playing a version of thecommon term pre-recorded for the video game, a version is extracted froma real broadcast and played. In one embodiment, the render component 610alters the common term to make it more suitable for gameplay (e.g.,lowers volume, changes tone, replaces a player name, removes possiblyoffensive language, etc.).

While aspects disclosed herein discuss that the render component 610produces a video game output 630, the render component 610 (and othercomponents) can function to produce non-video game outputs. Thus,aspects disclosed herein can have applicability outside of the videogame realm.

FIG. 7 illustrates one embodiment of a system 700 that includes anidentification component 705 and an approximation component 710 alongwith the collection component 605 and the render component 610. Theidentification component 705 can be configured to identify missinginformation in the physical information set (e.g., obtained from thephysical information sources 615, 620, and 625). The approximationcomponent 710 can be configured to determine a substitute informationset for the missing information, where the video game output 620 isbased, at least in part, on the physical information set and thesubstitute information set.

The collection component 605 can receive a user request for a map to bemade of a dirt road area for a rally car racing video game. Thecollection component 605 can obtain information pertaining to the dirtroad area, including information related to how road are configured,weather conditions, and the like. However, some information about theroad area may be unavailable. For example, what type of dirt the road ismade up of, a mixture ratio of different dirt types for a road surface,and other information may be unavailable. The identification component705 can identify the missing information (e.g., compare availableinformation against information used to create previous map, compareavailable information against hardcoded information listed as desirable,etc.). The approximation component 710 can compensate for this missinginformation by generating substitute information. For example, an aerialphotograph of the dirt road area can show the road being a certaincolor. The approximation component 710 can estimate a road dirt typebased on this color. The render component 610 can produce the video gameoutput 630 that is consistent with the estimated road dirt type. Thevideo game output 630 can be a racing track where the track responds ina manner consistent with the estimated dirt type.

FIG. 8 illustrates one embodiment of a system 800 that includes amonitor component 805, an appraisal component 810, and a decisioncomponent 815 in addition to the collection component 605 and the rendercomponent 610. The monitor component 805 can be configured to monitor acontent 820 presented by way of an electronic device (e.g., a videodisplayed on a television, a song played on a personal computer speakersystem, a webpage visited on a smartphone, etc.). It is to beappreciated that the system 800 can function without the monitorcomponent 805. The appraisal component 810 can be configured to evaluatethe content 820. The decision component 815 can be configured toproactively (e.g., automatically) select the video game output 820 forproduction (e.g., send an instruction to the render component 810 onwhat video game output 820 the render component 610 should produce)based, at least in part, on a result from evaluating the content 820.

The system 800 can function to provide a user with content the user islikely to want. For example, a user can watch a car race on televisionon a particular track. The system 800 can make an inference (e.g.,through use of at least one artificial intelligence technique) that theparticular track should be created for the user after the monitorcomponent 805 monitors the content 820. In one embodiment, before movingfurther the system 800 can confirm with a user that the track should berendered as video game output 620 (e.g., through a user interface) andthe decision component 815 instructs components to go forward based, atleast in part, on the user confirmation. The appraisal component 810 canevaluate the content and based on this evaluation, the collectioncomponent 605 can seek out information about the particular track, suchas recording the content 820 (e.g., on a computer readable medium),performing an Internet search for a website of the particular track anddownloading results, and others. This information can be used by therender component 610 to produce the video game output 630.

In one embodiment, a user can be watching a classic baseball game atTiger Stadium in Detroit, Mich. on a smartphone, where the classicbaseball game is the content 820. The monitor component 805 can monitorthe content 820 (e.g., extract information from the content 820, wherethe extracted information is a monitoring result). The appraisalcomponent 810 can evaluate the content 820 (e.g., the content 820itself, information extracted from the content 820, inferences drawnfrom monitoring the content 820, etc.) and based on this evaluation, thedecision component 815 can decide if the video game output 630 should beproduced based on the content 820, determine if enough information isavailable to produce the video game output 630 (e.g., if so, theninstruct the render component 610 to operate; if not, then cause thecollection component 605 to gather more information), etc.

FIG. 9 illustrates one embodiment of a system 900 that includes anassessment component 905, determination component 910, filter component915, and output component 920. The system 900 can incorporate theanalysis component 105 of FIG. 1, production component 110 of FIG. 1,the collection component 605 of FIG. 6, and/or the render component 610of FIG. 6. Different pieces of map data 925 (e.g., that are part of themap data set 115 and/or obtained by the sources 615, 620, and/or 625)can be collected by the system 900. Example map data can includepersonal images, map application data, text (e.g., available online fora message board), microblogging (e.g., used to ascertain real-timetraffic information), new information service broadcasts (e.g., trafficaccident reports from new organizations), and others.

The assessment component 905 can evaluate the map data and thedetermination component 910 can determine which map data 925 to use inrendering and/or updating a map. In one example, different pieces of mapdata can contradict one another.

In one example, an information source states that traffic on Main Streetis heavy while a news report states that traffic on Main Street ismedium. In an embodiment, the information source can be a real-time feedor stream such as a microblog (e.g., Twitter) or feed from a social,news or government network (e.g., Facebook news feed, local media RSS(Really Simple Syndication) feed, state police network, etc.). Thedetermination component 910 can determine if traffic on Main Street isheavy or medium (e.g., a determination is made that traffic is medium ifintelligence of the determination component 910 weighs the news reportas more accurate than the microblog (e.g., microblogs in general, aspecific person who made the microblog, and others)).

In one example, two photographs (e.g., a first photograph and a secondphotograph) are collected by the system 900 and evaluated by theassessment component 905. In the first photograph a light pole is showncolored green. In the second photograph, the light pole is shown ascolored blue. The determination component 910 can determine what colorto make the light pole in an output (e.g., the rendered map 120 of FIG.1). In one example, the determination component 910 can analyze when thephotographs were taken and information in a more recent photograph isused (e.g., date stamp, Exchangeable Image File Format (EXIF)information, Extensible Metadata Platform (XMP) information,International Press Telecommunications Council (IPTC) metadatainformation, other metadata, an inference such as that the pole waspainted and therefore the more recent photograph is more accurate, andothers). In one example, the determination component 910 can activelyseek out information to be used in determining a color for the lightpole (e.g., find other photographs, acquire a real-time satellite image,and others).

The filter component 915 can limit map data 925 transferred to theoutput component 920 (e.g., the output component 920 functioning as theproduction component 110 of FIG. 6, the output component 920 functioningas the render component 610 of FIG. 6, etc.). In one embodiment, thedetermination component 910 instructs the filter component which piecesof map data 925 should be passed to the output component 920 (e.g., usedto create a map). The output component 920 can render a map based on themap data 925 (e.g., map data 925 passed through the filter component915). The output component 920 can produce a map output 930 (e.g., therendered map 120 of FIG. 1, a data set upon which the productioncomponent 110 of FIG. 1 renders a map, an instruction on how to modifythe rendered map 120 of FIG. 1, the video game output 630 of FIG. 6,etc.).

In one embodiment, information related to a person can be usedproactively create data (e.g., a gaming map) for the person. In oneexample, a person could frequent message boards and write posts statingthat they wished they could play a first person shooter on the moon,send messages to friends (e.g., e-mails) expressing this desire, andothers. Based on the posts and messages, an inference could be drawnthat the player wants to play a map of the moon in a game she commonlyplays. The system 900 can proactively gather map data 925 that pertainsto the moon and proactively generate the map output 930 of the moon forplay in the game.

Similarly, a map can be modified based on information. In one example, aperson can play a map on a first person shooter game. In this map, anunintentional game aspect can occur that a person considers a cheat. Inthis example, players may play on opposing teams and have a goal ofcapturing and retaining checkpoints to achieve a team score. However, amap can include a feature where players on one team can lob grenadesacross a game board in an unrealistic and/or unfair manner toward one ofthe checkpoints that kills members of the opposing team. A component canfunction to identify this supposed cheat, determine if a proactivemodification of the map and/or the game should occur, and if a positivedetermination is made, then to modify the map and/or the game. Variousoutcomes can cause proactive modification and different modificationscan occur. In one instance, the modification can be in response toobserved player behavior (e.g., players skipping a map adisproportionate amount of times (e.g., when disproportionate skippingis identified, analyzing conduct to infer why skipping occurs)),response to complaints filed against a certain player who is performingthe supposed cheat, response to conversations over a network hosting thegame complaining of the supposed cheat, and others. The modification caninclude modifying the map to render the supposed cheat inoperable (e.g.,placing a barrier (e.g., real or invisible) such that the cheat isdisabled), modifying the game (e.g., causing the grenade to explode ifsent from a certain angle, from a certain spot, from a certain spot witha certain angle, from a certain weapon, etc.), modifying the game and/ormap locally, modifying the game and/or map universally, and others.Enabling proactive modification can enable a game to be improved afterlater versions are out, a game is no longer supported by a manufacturer,and others.

FIG. 10 illustrates one embodiment of a system 1000 that includes anobtainment component 1005, a gather component 1010, a generationcomponent 1015, and a transfer component 1020. The system 1000 canincorporate the analysis component 105 of FIG. 1, production component110 of FIG. 1, the collection component 605 of FIG. 6, and/or the rendercomponent 610 of FIG. 6. A person can make a request 1025 for a map tobe generated and the obtainment component 1005 (e.g., operating as thecollection component 605 of FIG. 6) collects the request 1025. In oneembodiment, the request 1025 is for a specific area to be created (e.g.,a map of Bonneville Salt Flats). In one embodiment, the request 1025 isfor a specific area with specific characteristics (e.g., a map of NewOrleans on Fat Tuesday (e.g., with roads closed for parade routes), amap of New York City in heavy traffic, a map of Glasgow, Scotland inheavy rain, and others). In one embodiment, the request 1025 is ageneral request (e.g., a request for a random map to be created).

The gather component 1010 can be employed to gather information. In oneembodiment, the gather component 1010, obtainment component 1005, andcollection component 605 of FIG. 6 can implement as one component. Inone embodiment, a requested map may already exist (e.g., on a database,on a game console, and others). If a requested map already exists, thenthe gather component 1010 can collect the requested map and therequested map can be outputted as output 1030 (e.g., by the transfercomponent 1020 and without passing the map through the transfercomponent).

In one embodiment, the gather component 1010 searches for a map meetingthe request 1025 and identifies a map that meets the request 1025 at alocation. The transfer component 1020 can cause the map that meets therequest 1025 to transfer to a location designated in the request 1025(e.g., transfer directly without residing on the system 1000).

In one embodiment, the gather component 1010 identifies informationsources and collects information that can be used in generating arendered map. Based on collected information, the generation component1015 can construct a map for use on a computer (e.g., a video game, atraining map, a movie (e.g., a map used in a cartoon), and others). Thetransfer component 1020 can transfer the map as output 1030 (e.g., therendered map 120 of FIG. 1, the video game output 630 of FIG. 6, etc.).

In one embodiment, a base map (e.g., base map 210 of FIG. 5) for arequested map is available. The gather component 1010 can collect thebase map. In one example, the person requests a map of Lucas County,Ohio. Maps may be available for Toledo, Ohio; Sylvania, Ohio; andOregon, Ohio (e.g., these three cities for the base map). However, mapsmay not be available for Maumee, Ohio as well as for villages andtownships of Lucas County, Ohio. Therefore, the gather component 1010collects information on how to render Maumee, Ohio as well as forvillages and townships of Lucas County, Ohio. The generation component1015 renders a map and the transfer component 1020 outputs the map(e.g., as output 1030).

In one embodiment, the base map is a map of a city and the generationcomponent 1015 modifies the map for specific characteristics. In oneexample, the city is Tyler, Tex. and a base map for Tyler, Tex. isavailable. However, the request 1025 can include a portion thatspecifies racing in a hot temperature. A hot temperature can change roadconditions. The base map for Tyler, Tex. can be configured to functionwith average temperature properties. The generation component 1015 canmodify the base map to change properties to those of hot temperature. Inone embodiment, public or private weather services or other informationsources can be consulted for these purposes (e.g., cause map to reflectweather that is actual/real-time, representative of historic trends,user-selected, etc.). In one embodiment, how roads in Tyler, Tex. reactto hot temperatures can be reflected in the output 1030.

In one embodiment a player requests (e.g., through the request 1025) foran arena to be created (e.g., a modern-day Madison Square Garden, a 1920Madison Square Garden set-up for a fight between Jack Dempsey and BillBrennan, a Madison Square Garden with player requested modifications,and others) for play in a boxing game. The gather component 1010 cansearch the Internet for images and information on Madison Square Garden.In one example, if the request 1025 is for the 1920 Madison SquareGarden set-up for the fight between Jack Dempsey and Bill Brennan, thenthe gather component 1010 can search the Internet to find archivedphotographs, newspaper descriptions, and others. Based on data collectedby the gather component 1010, the generation component 1015 can createthe arena and the transfer component 1020 can transmit the arena asoutput 1030 (e.g., transmit the arena to a game console).

FIG. 11 illustrates one embodiment of a system 1100 that includes anexamination component 1105, an identification component 1110, aseparation component 1115, and a generation component 1120. The system1100 can incorporate the analysis component 105 of FIG. 1, productioncomponent 110 of FIG. 1, the collection component 605 of FIG. 6, and/orthe render component 610 of FIG. 6. Map information 1125 (e.g., the mapinformation is the map data set 115 of FIG. 1 and/or is obtained fromthe sources 615, 620, and 625 of FIG. 6) can be collected (e.g.,actively (e.g., the system 1100 seeks out map information) and/orpassively (e.g., map information is sent to the system 1100 (e.g.,directly (e.g., by another unit) or indirectly (e.g., radio waves)))) bythe system 1100 and evaluated by an examination component 1105. Thesystem 1100 can be configured to render a map 1130 based off a specificlocation. However, a desire may exist for a map to not be a correctrepresentation of the specific location. In one example, a person canrequest to have a map made of Windsor, Ontario, Canada. However, somereal-life roads may include adult establishments (e.g., casino, stripclubs, night clubs, and others). The desire may be to mask these adultestablishments from a child, so if a person making a map request is achild, the system 1100 can filter out adult aspects when producing themap 1130 (e.g., the map 1130 can be the rendered map 120 of FIG. 1, themap 1130 can be video game output 630 of FIG. 6, etc.).

The examination component 1105 can examine the map information 1125 andproduce an examination result. The identification component 1110 can usethe evaluation result to identify items to not be rendered in the map1110. In one example, parental controls can at least partially controlintelligence used by the identification component 1110 to identify mapinformation not to be used, replaced, and other in the map 1130. In oneembodiment, the identification component 1110 can identify copyrightedinformation and cause the copyrighted information to be replaced in arendered map. In one embodiment, the identification component 1110functions by scanning photographs for copyrighted information,inappropriate content (e.g., sexually suggestive advertisements), etc.

In one embodiment, the system 1100 can function to replaceadvertisements with targeted advertisements. In one example, theidentification component 1110 can identify unused advertisementlocations in the map information 1125, identify advertisements that canbe replaced, as well as select advertisements for use (e.g., based onaggression levels, personal history, contract fulfillment, and others).

The separation component 1115 can filter out map information not to berendered, not to be considered in rendering, and others. The generationcomponent 1120 can take information produced out of the separationcomponent 1115 and render the map 1130 or cause the map 1130 to berendered (e.g., at another location). In one embodiment, the generationcomponent 1120 modifies the rendered map 120 of FIG. 1. In oneembodiment, the production component 110 of FIG. 1 and/or the rendercomponent 610 of FIG. 6 function as the generation component 1120.

FIG. 12 illustrates one embodiment of a system 1200 that includes theexamination component 1105, the identification component 1110, anapproximation component 1205, and a composition component 1210. Thesystem 1200 can incorporate the analysis component 105 of FIG. 1,production component 110 of FIG. 1, the collection component 605 of FIG.6, and/or the render component 610 of FIG. 6. The system 1200 cancollect map information 1215 (e.g., the map data set 115 of FIG. 1) andthe examination component 1105 can evaluate the map information 1215.The examination component 1105 can evaluate the map information 1215, atleast in part, with regards to if there are any unknown areas.

In one embodiment, the map information 1215 may be deficient orotherwise less than ideal for a particular context or in a particularinstance. In one example, the map information is to train submarinecrews on navigating oceans. However, specific information at deep oceandepths may not be available. Therefore, the system 1200 can makeapproximations. The identification component 1110 can identify areasthat are appropriate for approximation and the approximation component1205 can make approximations of these areas.

In one example, a map is designated for creation of an area of ocean ata deep depth. Actual map information related to the area at the deepdepth may not be available. However, the system 1200 may be able toobtain auxiliary information. Example auxiliary information can include:wildlife found in the region and are comfortable around the deep depth,scientific calculation information (e.g., pressure at the depth, naturallight that would make it to the depth, and others), information derivedfrom ocean models, and others.

The composition component 1210 (e.g., production component 110 of FIG.1, render component 610 of FIG. 6, etc.) can create a map based onapproximation information and map information 1215. The map can beoutputted as an outputted map 1220 (e.g., rendered map 120, video gameoutput 630, etc.). In one embodiment, the composition component 1210 cancause a component to create a map and/or output a map (e.g., send aninstruction to the production component 110 of FIG. 1 to create therendered map 120 of FIG. 1).

In one embodiment, the outputted map 1220 can be evaluated to determineif approximations are appropriate. If approximations are appropriate,then the outputted map 1220 can be transmitted (e.g., caused to betransmitted, caused to be rendered, caused to be created, and others).If an approximation is not appropriate, then the system 1200 candetermine how to correct the approximation (e.g., through implementationof an artificial intelligence technique) and correct the approximation.Another check can occur, this can repeat if appropriate, and theoutputted map 1220 can be outputted. In one embodiment, approximationscan be noted (e.g., in a file associated with the outputted map 1220)and as new map information is gathered, the approximations can bereplaced with real map information, approximations can be modified asnew information is available, and others.

In one embodiment, the outputted map 1220, the video game output 630 ofFIG. 6, the rendered map 120, and others can be checked for accuracyafter production. In one example, the examination component 1105 cancompare the rendered map 120 of FIG. 1 against the map data set 115 ofFIG. 1 to determine if the rendered map 120 of FIG. 1 is an accuraterepresentation of the map data set 115 and/or actual location. If therendered map 120 of FIG. 1 is not an accurate representation, then therendered map 120 of FIG. 1 can be corrected, a subsequent rendered mapcan be generated, an error message can be presented, etc. In oneembodiment, to avoid correction, the rendered map 120 of FIG. 1 can havea similarity threshold to the map data set 115 of FIG. 1 (e.g., renderedmap 120 of FIG. 1 is X % similar to the map data set 115 of FIG. 1).

In one example, a football video game can be released with an error(e.g., a rendered stadium can show a running track around a field when areal stadium upon which the rendered stadium is based has no track). Auser can submit information that an error occurred, an inference can bedrawn that users are using a map editor to correct the error, acomparison can be made with photographic evidence publically available(e.g., off an Internet map application), and others. A result can occurwhere new releases and/or existing releases can be updated correctingthe error (e.g., updated automatically). In one example, a stadium canbe rendered correctly (e.g., as the rendered map 120 of FIG. 1), butover a season or over time a change can occur. In one example, lightingpoles can be painted from one color to another. When this information islearned, an update can occur (e.g., occur proactively).

FIG. 13 illustrates one embodiment of a system 1300 that includes theexamination component 1105, the identification component 1110, thecomposition component 1210, and a database component 1305. The system1300 can incorporate the analysis component 105 of FIG. 1, productioncomponent 110 of FIG. 1, the collection component 605 of FIG. 6, and/orthe render component 610 of FIG. 6. Map information 1310 can becollected by the system 1300. The examination component 1105 can analyzethe map information 1310 and based on this analysis, the identificationcomponent 1110 can identify map information 1310 that can be used tocreate a map 1320 (e.g., the rendered map 120 of FIG. 1 produced by theproduction component 110 of FIG. 1).

In one embodiment, the system 1300 is part of a network that shares adatabase 1315. The database 1315 can retain maps that can be madeavailable to network members (e.g., on a wired network, on a wifinetwork, on a super wifi network, and others). The map 1320 (e.g., theoutputted map 1220 of FIG. 12, the rendered map 120 of FIG. 1, etc.) canbe retained on the database 1315 (e.g., in addition to transferring themap to a designated destination).

In one embodiment, the system 1300 can receive a request for a map 1320(e.g., a map of Normandy, France on Jun. 6, 1944). A check can occur bythe system 1300 (e.g., by the examination component 1105) to determineif the database 1315 includes the map 1320. If the database 1315 doesinclude the map 1320, then the system 1300 is caused to output the map1320 (e.g., cause the map 1320 to be sent directly from the database1315). If the database 1315 does not include the map 1320, system 1300can create the map 1320 (e.g., as the map of Normandy, France on Jun. 6,1944).

In one embodiment, a check is performed to determine if the database1315 does not include the map 1320. However, the database 1315 mayinclude a modern-day map of Normandy, France. The system 1300 can gatherthe modern-day map of Normandy, France and collect historicalinformation about Normandy, France on Jun. 6, 1944. The compositioncomponent 1210 can modify (e.g., modify a local copy) and/or base a newmap off the modern-day map of Normandy, France.

In one embodiment, the database 1315 is in a central location. In oneembodiment, the database 1315 is distributed across a network of nodes.In one embodiment, the database 1315 is distributed across individualunits (e.g., individual game consoles).

FIG. 14 illustrates one embodiment of a network 1400. The network 1400can include a first game console 1405 and a second game console 1410.The first game console 1405 and/or the second game console 1410 canincorporate the analysis component 105 of FIG. 1, production component110 of FIG. 1, the collection component 605 of FIG. 6, and/or the rendercomponent 610 of FIG. 6 (e.g., a combination thereof). The first gameconsole 1405 can retain a first map 1415 and the second game console1410 can retain a second map 1420. The network 1400 can be a localnetwork, a network over the Internet, and others. While shown with twogame consoles and two maps, it is to be appreciated that the network1400 can include more than two game consoles, more than two maps, anyone particular game console can retain more than one map, and others.

The network 1400 can function such that individual game consoles canhave access to a vast amount of maps while retaining relatively few mapslocally. In one example, the first game console 1405 retains first map1415 locally. However, first game console 1405 can have access to thesecond map 1420 retained on second game console 1410.

In one embodiment, a player using first game console 1405 can request toplay second map 1420. A permission and/or security check can occur andbased on a positive result, the player can play second map 1420. In oneexample, a check is made to determine if the player using first gameconsole 1405 makes first map 1415 available to other game consoles.Sharing or exchange schemes can be enforced according to ratios,purchase, bargaining, trading, credits or money, and other methods ofmap-swapping including user preferences, map popularity andavailability, resource intensity or size, relationship or friend status,necessity (e.g., to play in a tournament or with friends), and a varietyof other techniques. In an embodiment, one user can give a specific mapaway for free while another requires an exchange. In one embodiment,users are designated to offer the same map (or other information) forthe same value.

In one embodiment, the first map 1415 and the second map 1420 are mapsdepicting a specific location (e.g., both maps are of Lake Erie). Themaps can be identical or be different (e.g., one map is of a higherquality than the second map, the maps have contrasting information, thefirst map 1415 is configured for a fishing game and has a relativelylarge amount of fishing data while the second map 1420 is boating mapthat has a relatively large amount of wave information, and others). Asearch can occur for a map of the specific location. A component candetermine which map to access. In one example, if the maps areidentical, then a component can select a map (e.g., a cheaper map can beselected, a map that can be downloaded faster can be selected, andothers). In one example, if the maps are different, then a component canselect a map (e.g., if a player wants to used a searched map a fishinggame, then the first map 1415 is selected; if the player wants to usethe searched map in an first person shooter game, then a determinationcan be made on which map can be more easily converted and/or has moreuseful metadata (e.g., wave information that can impact travelling onthe water) and that map can be selected; and others).

In one embodiment, second map 1420 is downloaded onto first game console1405 and retained (e.g., saved after play is completed, temporarilyretained until done playing, and/or others). In one embodiment, thefirst game console 1405 can play the second map 1420 while keeping thesecond map 1420 on the second game console 1410. In one embodiment, maps(e.g., first map 1415 and second map 1420) are distributed among gameconsoles (e.g., first game console 1405 and second game console 1410)and/or other locations (e.g., databases). In one embodiment, in responseto a request by a player on first game console 1405 to play second map1420, second map 1420 can be retained on first game console 1405 andfirst map 1415 can be removed off first game console 1405 and retainedon second game console 1410 (e.g., first game console 1405 and secondgame console 1410 switch locally-stored maps).

In one embodiment, first map 1415 and second map 1420 can be gaming mapsfor use in a shooter video game (e.g., first-person shooter). In oneembodiment, first map 1415 and second map 1420 can be based onreal-world areas and rendered by the system 100 of FIG. 1. In oneexample, first map 1415 can be used in a real-world combat simulationgame of a city in Iraq and second map 1420 can be used in a fictionalspace invasion combat arcade game. The system 100 of FIG. 1 can use acomponent to modify (e.g., intelligently modify) a map to make a mapmore game combat friendly. In an embodiment, first map 1415 can be usedon first game console 1405 as a racing video game map, and used onsecond game console 1410 as a shooter video game map. Features (e.g.resolution, detail, background interaction, background behavior, andothers) can be adjusted to better accommodate the particular gaming (orother) context to which a particular map is applied. In one embodiment,a map can be converted from a first type (e.g., a shooter map) to asecond type (e.g., a racing map).

A security component can be used to determine if rendering should occur,to stop a rendering from occurring, and others. In one example, a childcan request that a map be rendered of his school for a first-personshooter game. While the map may be rendered from available information(e.g., information from a map application, publically availableblueprints, photographs from a social networking site that showdecorations, content from a school website, academic or educationalgames and applications, and others), there may be a social desire to notenable a student to play a game where shootings can happen in school.Therefore, the security component can stop the rendering from occurring,report the requested rendering, stop the rendering if the requestormeets a metric (e.g., is a student at the school, is underage, andothers), and others. In one embodiment, the security component isintegrated as part of the production component 110 of FIG. 1.

The following methodologies are described with reference to figuresdepicting the methodologies as a series of blocks. These methodologiesmay be referred to as methods, processes, and others. While shown as aseries of blocks, it is to be appreciated that the blocks can occur indifferent orders and/or concurrently with other blocks. Additionally,blocks may not be required to perform a methodology. For example, if anexample methodology shows blocks 1, 2, 3, and 4, it may be possible forthe methodology to function with blocks 1-2-4, 1-2, 3-1-4, 2, 1-2-3-4,and others. Blocks may be wholly omitted, re-ordered, repeated or appearin combinations not depicted. Individual blocks or groups of blocks mayadditionally be combined or separated into multiple components.Furthermore, additional and/or alternative methodologies can employadditional, not illustrated blocks, or supplemental blocks not picturedcan be employed in some models or diagrams without deviating from thespirit of the features. In addition, at least a portion of themethodologies described herein may be practiced on a computer-readablemedium storing computer-executable instructions that when executed by acomputer cause the computer to perform a methodology (e.g., method).

FIG. 15 illustrates one embodiment of a method 1500 that includesretaining a video game content at a first location 1505 and causing thevideo game content to be available to a second location 1510. The method1500 can function in association with the network 1400 of FIG. 14. Inone embodiment, the first game console 1405 of FIG. 14 can be the firstlocation, the second game console 1410 of FIG. 14 can be the secondlocation, the first map 1415 of FIG. 14 and/or the second map 1420 ofFIG. 14 can be the video game content. In one embodiment, the video gamecontent (e.g., rendered map 120 of FIG. 1, video game output 630 of FIG.6, etc.) can be produced and then retained at 1505 by the productioncomponent 110 of FIG. 1 (e.g., retained in a computer-readable medium,retained in a computer-readable medium by a processor functioning as theproduction component 110 of FIG. 1). In one embodiment, the productioncomponent 110 of FIG. 1 causes the video game content to be available at1510

In one embodiment, the first location 1505 is a first video gameconsole, the second location 1510 is a second video game console, andthe first video game console is remote to the second video game console.In one embodiment, the video game content is distributed across thefirst location 1505 and the second location 1510 and/or stored at thefirst location 1505 or second location 1510 alone. In one embodiment,the video game content is a video game map. In one embodiment, the videogame content is created at the first location 1505. In one embodiment,the video game content is created at the second location 1510. In oneembodiment, the video game content is created at a separate location(e.g., a computer system at a company office that is then sent to thefirst location 1505). In one embodiment, the video game content is afirst video game content (e.g., the first map 1415 of FIG. 14) and wherethe second video game console (e.g., the second game console 1410 ofFIG. 14) retains a second video game content (e.g., the second map 1420of FIG. 14) that is available to the first video game console (e.g., thefirst game console 1405 of FIG. 14).

FIG. 16 illustrates one embodiment of a method 1600 that includesretaining a video game content at the first location 1505 of FIG. 15 andcausing the video game content to be available to the second location1510 of FIG. 15. At 1605, a physical information set is obtained (e.g.,in response for a video game content request from entered at the firstlocation 1505 of FIG. 15). In one embodiment, the physical informationis obtained by the collection component 605 of FIG. 6. At 1610, thephysical information set is evaluated. This evaluation can be performedby the analysis component 105 of FIG. 1 and/or the examination component1105 of FIG. 11. The video game content can be produced at 1615. Thisproduction can be based, at least in part, on a result from evaluatingthe physical information set at 1610. In one embodiment, this productioncan be performed by the production component 110 of FIG. 1 and/or therender component 610 of FIG. 6.

FIG. 17 illustrates one embodiment of a method 1700 that resolves adifference between maps. At 1705, the method 1700 can process maps(e.g., collect maps, evaluate maps, compare maps against one another,compare maps against other information, and others). Based on mapprocessing, a determination can be made on map differences at 1710(e.g., if at least one map difference exists, why a map differenceexists, and others). At 1715, a determination can be made on how toresolve a map difference. At 1720, a resolution to resolve the mapdifference can be caused to implement (e.g., send an instruction to theproduction component 110 of FIG. 1 on how to create a map, theproduction component 110 of FIG. 1 makes the resolution, etc.). In oneembodiment, a solution to resolve the map difference can be testedbefore implementation.

FIG. 18 illustrates one embodiment of a method 1800 that causes a map tobe made (e.g., a new map to be created, a map to be modified, a map tobe replaced, and others). Information (e.g., the map data set 115 ofFIG. 1) can be collected at 1805. Information can include mapapplication information, request information, information found off theInternet and others. Information can be collected passively (e.g., sentto a computer-readable medium operating the method 1800) and/or actively(e.g., the computer-readable medium operating the method 1800 seeks outinformation).

The information can be analyzed at 1810. At 1815, a determination can bemade on how to make a map (e.g., based on a result of the analysis). Inone embodiment, the information collected at 1805 includes instructionsand/or format data for a device that may ultimately use the map. At1820, a map can be caused to be made (e.g., according to a mannerdetermined at 1815). In one embodiment, the map can be made and causedto be displayed, caused to be used in an application (e.g., softwareapplication), and others.

FIG. 19 illustrates one embodiment of a town grouping 1900. The towngrouping 1900 can include various towns (e.g., Towns A-I). In oneexample, the town grouping 1900 represents a larger organization (e.g.,Towns A-I form a county J).

An interface can be presented to a person that enables the person todesignate an area for rendering (e.g., by the production component 110of FIG. 1, by the render component 610 of FIG. 6, etc.). In one example,the person can access a personal computer and use a mouse and keyboardto designate a selected area 1905. A map of the selected area 1905 canbe rendered and transferred (e.g., to a personal computer, to a gameconsole, to a computer-readable medium, and others). While shown as arectangle, it is to be appreciated that the selected area can be variousshapes and/or arrangements.

In addition, a map can be rendered with a three-dimensional component(e.g., render from ground level to ‘x’ distance in the air). Theselected area 1905 can designate a third dimensional limit and/or onecan be inferred. As described above, maps can be altered to fit aparticular usage context. For example, one usage can be entirelytwo-dimensional, another can be three-dimensional wherein the thirddimension is treated as background or environment, and still anotherusage context can involve travel through three dimensions wherein thethird dimension is actively engaged with the particular use.

Additionally, an inference can be drawn on how to render map boundaries(e.g., how high to make a third dimension). In one embodiment, a map canbe rendered for a racing game. In this embodiment, rendering can belimited to a height of an upper limit of a car windshield. In oneembodiment, for specific situations (e.g., an in-game car flips over), amore generic setting can be shown (e.g., non-accurately rendered, butresembling other scenery).

FIG. 20 illustrates one embodiment of an interface 2000. A creationcomponent can create the interface 2000 and the interface can bedisclosed (e.g., caused to be disclosed). In one embodiment, thecreation component is part of the system 1000 of FIG. 10 and theinterface facilitates the request 1025 (e.g., by filling out theinterface 2000, the request 1025 is generated). Disclosure of theinterface 2000 can occur in response to a command, in response to aninference (e.g., conversation of players wishing they could play a gameon a particular circuit), and others. The creation component canidentify information that could be beneficial in knowing to create a mapand produce the interface 2000. In one embodiment, a person creates theinterface 2000 (e.g., a programmer, a player, and others). At least somefields of the interface 2000 can be populated with data and based, atleast in part, on the data a map can be rendered.

FIG. 21 illustrates one embodiment of a system 2100 that may be used inpracticing at least one aspect disclosed herein. The system 2100includes a transmitter 2105 and a receiver 2110. In one or moreembodiments, the transmitter 2105 can include reception capabilitiesand/or the receiver 2110 can include transmission capabilities. In oneembodiment, the system 100 of FIG. 1 includes the transmitter 2105and/or the receiver 2110. In one embodiment, the receiver 2110integrates with and/or functions as the collection component 605 of FIG.6 and the transmitter 2105 integrates with and/or functions as therender component 610 of FIG. 6. In one embodiment, the system 100 ofFIG. 1 and/or the system 600 of FIG. 6 integrate with the system 2100 ona mobile device.

The transmitter 2105 and receiver 2110 can each function as a client, aserver, and others. The transmitter 2105 and receiver 2110 can eachinclude a computer-readable medium used in operation. Thecomputer-readable medium may include instructions that are executed bythe transmitter 2105 or receiver 2110 to cause the transmitter 2105 orreceiver to perform a method. The transmitter 2105 and receiver 2110 canengage in a communication with one another. This communication can overa communication medium. Example communication mediums include anintranet, an extranet, the Internet, a secured communication channel, anunsecure communication channel, radio airwaves, a hardwired channel, awireless channel, and others. Example transmitters 2105 include a basestation, a personal computer, a cellular telephone, a personal digitalassistant, and others. Example receivers 2110 include a base station, acellular telephone, personal computer, personal digital assistant, andothers. The example system 2100 may function along a Local AccessNetwork (LAN), Wide Area Network (WAN), and others. The aspectsdescribed are merely an example of network structures and intended togenerally describe, rather than limit, network and/or remoteapplications of features described herein.

FIG. 22 illustrates one embodiment of a system 2200, upon which at leastone aspect disclosed herein can be practiced. In one embodiment, thesystem 2200 can be considered a computer system that can function in astand-alone manner as well as communicate with other devices (e.g., acentral server, communicate with devices through data network (e.g.,Internet) communication, etc). Information can be displayed through useof a monitor 2205 and a user can provide information through an inputdevice 2210 (e.g., keyboard, mouse, touch screen, etc.). In oneembodiment, the monitor 2205 displays the interface 2000 of FIG. 20. Aconnective port 2215 can be used to engage the system 2200 with otherentities, such as a universal bus port, telephone line, attachment forexternal hard drive, and the like. Additionally, a wireless communicator2220 can be employed (e.g., that uses an antenna) to wirelessly engagethe system 2200 with another device (e.g., in a secure manner withencryption, over open airwaves, and others). A processor 2225 can beused to execute applications and instructions that relate to the system2200. In one example, the processor 2225 executes at least oneinstruction associated with at least one of the analysis component 105of FIG. 1 or the production component 110 of FIG. 1. In one example, theprocessor 2225 executes at least one instruction associated with atleast one of the collection component 605 of FIG. 6 or the rendercomponent 610 of FIG. 6. Storage can be used by the system 2200. Thestorage can be a form of a computer-readable medium. Example storageincludes random access memory 2230, read only memory 2235, ornonvolatile hard drive 2240. In one embodiment, a memory (e.g., at leastone of the random access memory 2230, read only memory 2235, and/or thenonvolatile hard drive 2240) retains instructions that cause a methoddisclosed herein to operate. In one embodiment, the memory retains adatabase in accordance with at least one aspect disclosed herein.

The system 2200 may run program modules. Program modules can includeroutines, programs, components, data structures, logic, etc., thatperform particular tasks or implement particular abstract data types.The system 2200 can function as a single-processor or multiprocessorcomputer system, minicomputer, mainframe computer, laptop computer,desktop computer, hand-held computing devices, microprocessor-based orprogrammable consumer electronics, and the like.

It is to be appreciated that aspects disclosed herein can be practicedthrough use of artificial intelligence techniques. In one example, adetermination or inference described herein can, in one embodiment, bemade through use of a Bayesian model, Markov model, statisticalprojection, neural networks, classifiers (e.g., linear, non-linear,etc.), using provers to analyze logical relationships, rule-basedsystems, or other technique.

While example systems, methods, and so on have been illustrated bydescribing examples, and while the examples have been described inconsiderable detail, it is not the intention of the applicants torestrict or in any way limit the scope of the appended claims to suchdetail. It is, of course, not possible to describe every conceivablecombination of components or methodologies for purposes of describingthe systems, methods, and so on described herein. Therefore, innovativeaspects are not limited to the specific details, the representativeapparatus, and illustrative examples shown and described. Thus, thisapplication is intended to embrace alterations, modifications, andvariations that fall within the scope of the appended claims.

Functionality described as being performed by one entity (e.g.,component, hardware item, and others) may be performed by otherentities, and individual aspects can be performed by a plurality ofentities simultaneously or otherwise. For example, functionality may bedescribed as being performed by a processor. One skilled in the art willappreciate that this functionality can be performed by differentprocessor types (e.g., a single-core processor, quad-core processor,etc.), different processor quantities (e.g., one processor, twoprocessors, etc.), a processor with other entities (e.g., a processorand storage), a non-processor entity (e.g., mechanical device), andothers.

In addition, unless otherwise stated, functionality described as asystem may function as part of a method, an apparatus, a method executedby a computer-readable medium, and other embodiments may be implementedin other embodiments. In one example, functionality included in a systemmay also be part of a method, apparatus, and others.

Where possible, example items may be combined in at least someembodiments. In one example, example items include A, B, C, and others.Thus, possible combinations include A, AB, AC, ABC, AAACCCC, AB, ABCD,and others. Other combinations and permutations are considered in thisway, to include a potentially endless number of items or duplicatesthereof.

What is claimed is:
 1. A computer-readable medium storingcomputer-executable instructions that when executed by a computer causethe computer to perform a method, the method comprising: identifyinginitialization of a first video game racing session at a first point intime, the first video game racing session is to play on a racing track;determining a first weather for the racing track that corresponds to thefirst point in time; causing the first video game racing session torender the racing track such that the surface of the racing trackcorresponds to a response the racing track has to the first weather;identifying initialization of a second video game racing session at asecond point in time, the second video game racing session is to play ona racing track; determining a second weather for the racing track thatcorresponds to the second point in time; and causing the second videogame racing session to render the racing track such that the surface ofthe racing track corresponds to a response the racing track has to thesecond weather, where the second point in time is after the first pointin time, where there is a difference between the first weather and thesecond weather, and where there is a difference between the response theracing track has to the first weather and the response the racing trackhas to the first weather.
 2. The computer-readable medium of claim 1,where the response the racing track has to the first weather comprises afirst amount of precipitation on the surface, the first amount beingequal to or greater than zero, where the response the racing track hasto the second weather comprises a second amount of precipitation on thesurface, the second amount being equal to or greater than zero, wherethere is a difference between the first amount and the second amount,where a first vehicle of the first video game racing session responds tothe surface with the first amount of precipitation in a first manner,where a second vehicle of the second video game racing session respondsto the surface with the second amount of precipitation in a secondmanner, where there is a difference between the first manner and thesecond manner, and where the first vehicle and the second vehicle arethe same vehicle.
 3. The computer-readable medium of claim 1, where theresponse the racing track has to the first weather comprises the surfacebeing at a first temperature for at least a portion, where the responsethe racing track has to the second weather comprises the surface beingat a second temperature for at least a portion, where there is adifference between the first temperature and the second temperature,where a first vehicle of the first video game racing session responds tothe surface at the first temperature in a first manner, where a secondvehicle of the second video game racing session responds to the surfaceat the second temperature in a second manner, where there is adifference between the first manner and the second manner, and where thefirst vehicle and the second vehicle are the same vehicle.
 4. Thecomputer-readable medium of claim 1, where the first weather is a firstreal-time-based weather, where the second weather is a firstreal-time-based weather, where the causing the first video game racingsession to render the racing track occurs on a single gaming console,and where the causing the second video game racing session to render theracing track occurs on the same gaming console.
 5. The computer-readablemedium of claim 1, where the first weather is a first real-time-basedweather, where the second weather is a first real-time-based weather,where the determining the first weather occurs from access of anInternet-based weather information source, where the determining thesecond weather occurs from access of the Internet-based weatherinformation source, where the causing the first video game racingsession to render the racing track is propagated upon a first gaminglocation remote to the computer-readable medium, and where the causingthe second video game racing session to render the racing track ispropagated upon a second gaming location remote to the computer-readablemedium and remote to the first gaming location.
 6. A system, that is atleast partially hardware, comprising: a determination componentconfigured to determine a real-world location designated for play in avideo game; an identification component configured to identify areal-time weather for the real-world location designated for play; and arender component configured to render a video game playable arearepresentative of the real-world location subjected to the real-timeweather.
 7. The system of claim 6, where the video game is a racingvideo game where a vehicle set drives with a tire set upon a racingsurface, where the racing surface is, at least part of, the video gameplayable area, and where the real-time weather impacts the racingsurface.
 8. The system of claim 7, where the real-time weather causes aremoval of a tire remnant of the vehicle set from the racing surface. 9.The system of claim 8, where the removal of the tire remnant causes alevel of the tire remnant to drop from a first level to a second level,where the first level is greater than zero, where the second level isgreater than zero, and where the level of the tire remnant influencesperformance of the vehicle set.
 10. The system of claim 7, where thereal-time weather causes a temperature change to the racing surface froma first temperature to a second temperature and where the vehicle setperforms differently on the racing surface with the first temperaturethan on the racing surface with the second temperature.
 11. The systemof claim 7, comprising: an inference component configured to perform aninference of a track temperature for the racing surface, where theinference is based, at least in part, on the real-time weather and wherethe render component renders the racing surface with the inferred tracktemperature.
 12. The system of claim 7, where the real-time weatherimpacts a temperature of the racing surface, where the vehicle setdriving on the racing surface impacts the temperature of the racingsurface, where the render component is configured to render the racingsurface with a temperature in accordance with the real-time weather anda result from the vehicle set driving on the racing surface.
 13. Thesystem of claim 7, where the racing surface comprises a first sectionand a second section, where the render component, in response to thereal-time weather, is configured to render the first section with afirst temperature, where the render component, in response to thereal-time weather, is configured to render the second section with asecond temperature, and where the first temperature and the secondtemperature are different temperatures.
 14. The system of claim 7,comprising: a selection component configured to select a surfacetemperature of the racing surface, where the determination component isconfigured to determine a surface type for the racing surface, where thereal-time weather comprise a real-time air temperature, where theselection of the surface temperature is based, at least in part, on thereal-time air temperature and the surface type, and where the rendercomponent renders the racing surface with the selected surfacetemperature.
 15. The system of claim 7, comprising: a selectioncomponent configured to select a surface temperature of the racingsurface, where the determination component is configured to determine asurface type for the racing surface, where the real-time weathercomprise a level of sun exposure, where the selection of the surfacetemperature is based, at least in part, on the level of sun exposure andthe surface type, and where the render component renders the racingsurface with the selected surface temperature.
 16. The system of claim6, comprising: where the video game playable area is employable in agaming session, where the identification component is configured to,during the gaming session, identify a change in the real-time weather,and where the render component is configured to update the video gameplayable area to reflect the change in the real-time weather.
 17. Thesystem of claim 6, comprising: a selection component configured toidentify a selection by a user for the video game playable area to berendered with the real-time weather, where the identification componentis configured to identify the real-time weather when the user makes theselection.
 18. A system, that is at least partially hardware,comprising: a determination component configured to determine areal-world location designated for play in a racing video game; anidentification component configured to identify a weather for thereal-world location designated for play; and a render componentconfigured to render a racing surface representative of the real-worldlocation subjected to weather such that the racing surface has atemperature reflective of the weather.
 19. The system of claim 18, wherethe weather is a first weather, where the temperature is a firsttemperature, where the identification component is configured toidentify a change such that the first weather is replaced by a secondweather for the real-world location during a racing session, where therender component is configured to cause the a racing surfacerepresentative of the real-world location subjected to have a secondtemperature replace the first temperature, where the second temperatureis reflective of the second weather, where an action for a gamingvehicle causes a first response by the gaming vehicle to the racingsurface when the racing surface is at the first temperature, where theaction for the gaming vehicle causes a second response by the gamingvehicle to the racing surface when the racing surface is at the secondtemperature, where there is a difference between the first temperatureand the second temperature, and where the first response and the secondresponse are different due, at least in part, to the difference betweenthe first temperature and the second temperature.
 20. The system ofclaim 18, comprising: a selection component configured to select asurface temperature of the racing surface, where the weather isidentified from a recent weather report for the real-world location,where the determination component is configured to determine a surfacetype for the racing surface, where the real-time weather comprise arecent air temperature and a recent accumulation of precipitation, wherethe recent accumulation of precipitation is greater than zero, where theselection of the surface temperature is based, at least in part, on therecent air temperature, the recent accumulation of precipitation, andthe surface type, and where the render component renders the racingsurface with the selected surface temperature.